RU2005112248A - DEVICE AND METHOD FOR TRANSMITTING / RECEIVING DATA IN A COMMUNICATION SYSTEM USING A MULTIPLE ACCESS SCHEME - Google Patents

Claims (30)

1. A method of transmitting data by a transmitter in a communication system that divides the entire frequency range into a plurality of sub-frequency ranges, namely, that n frame cells are designated as packet data transmission frame cells for transmitting packet data from among a plurality of frame cells, the frame cell being occupied during the first time interval, the set of time-frequency cells occupied by the second time interval and m sub-frequency ranges designates the remaining frame cells, except for the packet transmission frame cells data for transmitting packetized data, as cells of control data transmission frames for transmitting control data, and transmit packetized data through cells of packet data transmission frames if packetized transmission data exists, and transmit transmission control data through control data frame cells if transmission control data exists. 2. The method according to claim 1, wherein at least one of the cell frames is designated as a cell of control data transmission frames. 3. The method according to claim 1, in which the subfrequency from the ranges of subfrequencies that make up each of the time-frequency cells is hopped in accordance with a given frequency hopping scheme. 4. The method according to claim 1, in which each of the time-frequency cells is expanded using a predetermined code for allocating a frequency band to individual channels. 5. A method of transmitting data by a transmitter in a communication system that divides the entire frequency range into a plurality of sub-frequency ranges, which comprises receiving channel quality information for each of a plurality of frame cells occupied during the first time interval by a plurality of time-frequency cells occupied the second time interval and a given number of sub-frequency ranges transmitted over the feedback channel from the receiver, arrange the cell cells in accordance with the quality information of the channels, and transmit data Res frame cell according to the ordered channel quality information. 6. The method of claim 5, wherein the frame cells are sequentially ordered from a frame cell having the best channel quality to a frame cell having the worst channel quality. 7. The method according to claim 5, in which additionally transmit data through the cell frame having the second best quality channels, if there is no available subchannel for data transmission in the cell frame having the best quality channels. 8. The method according to claim 5, in which additionally, if in the cell frame having the best quality channels, there is a number of available subchannels, which is less than the number of subchannels required for data transmission, transmit part of the data through the available subchannels of the frame cell having the best channel quality, and transmit the remainder of the data through a frame cell having the next best channel quality. 9. The method according to claim 5, in which the data is packet data or control data, wherein the cell frames are classified into cell frames for transmitting packet data for transmitting packet data and cell frames for transmitting control data for transmitting control data, and channel quality information is transmitted on the feedback channel through the cells of the control data transmission frames. 10. The method according to claim 9, in which at least one of the cell frames is assigned as the cell of the control data transmission frames. 11. The method according to claim 5, in which the subfrequency from the ranges of subfrequencies that make up each of the time-frequency cells is hopped in accordance with a predetermined frequency hopping pattern. 12. The method according to claim 5, in which each of the time-frequency cells is expanded using a predetermined code for allocating a frequency band to individual channels. 13. The method of receiving data by the receiver in a communication system that divides the entire frequency range into multiple ranges, which consists in measuring the quality of channels of a plurality of frame cells occupied during a first time interval by a plurality of time-frequency cells occupied by a second time interval and a predetermined number sub-frequency ranges using a signal received from the transmitter, and channel quality information, measured for each of the frame cells, is transmitted to the transmitter via the feedback channel. 14. The method according to item 13, in which the cell frames are divided into cell frames for transmitting packet data for transmitting packet data and cell frames for transmitting control data for transmitting control data, and information about the quality of the channels is transmitted via the feedback channel through the cell frames for transmitting control data . 15. The method of claim 14, wherein at least one of the frame cells is designated as a control data transmission frame cell. 16. The method according to item 13, in which the sub-frequency from the ranges of sub-frequencies that make up each of the time-frequency cells, hopping in accordance with a given frequency hopping scheme. 17. The method according to item 13, in which each of the time-frequency cells is expanded using a predetermined code for allocating a frequency band to individual channels. 18. A data transmission device for a transmitter in a communication system that divides the entire frequency range into a plurality of sub-frequency ranges, comprising a channel quality information receiver for receiving channel quality information for each of the plurality of frame cells occupied during the first time interval by a plurality of time-frequency cells occupied by the second time interval and a given number of sub-frequency ranges transmitted over the feedback channel from the receiver, a frame cell ordering module for analyzing inform tion of a feedback channel and ordering the frame cells according to the channel quality information, and the destination module subchannels for data transmission through the cell frame according to the ordered channel quality information. 19. The data transmission device according to claim 18, wherein the frame cell sequencer module sequentially orders frame cells from a frame cell having the best channel quality to a frame cell having the worst channel quality. 20. The data transmission apparatus of claim 18, wherein the subchannel assignment module performs a data transmission control operation through subchannels of a frame cell having a second best channel quality if there is no subchannel available for transmitting data in a frame cell having the best channel quality. 21. The data transmission device according to p. 18, in which if in the cell cell having the best quality channels, there are fewer available subchannels than the number of subchannels necessary for data transmission, the subchannel assignment module performs a control operation by transmitting a portion of the data through the available subchannels a frame cell having the best channel quality and transmitting the remainder of the data through subchannels of a frame cell having the next best channel quality. 22. The data transmission apparatus of claim 18, wherein the data is one of data: packet data or control data, frame cells are classified into packet data transmission cell cells for transmitting packet data, and control data transmission cell cells for transmitting control data, and the information The quality of the channels is transmitted via the feedback channel through the cells of the control data transmission frames. 23. The data transmission device according to item 22, in which at least one of the frame cells is assigned as a cell of control data transmission frames. 24. The data transmission device according to claim 18, wherein the sub-frequency from the sub-frequency ranges constituting each of the time-frequency cells is hopped in accordance with a predetermined frequency hopping pattern. 25. The data transmission device according to claim 18, wherein each of the time-frequency cells is expanded using a predetermined code for allocating a frequency band to individual channels. 26. A device for receiving data for a receiver in a communication system that divides the entire frequency range into a plurality of subfrequency ranges, comprising a channel cell quality meter for measuring channel quality of a plurality of frame cells occupied by a plurality of time-frequency cells occupied by a second time interval and a given number of sub-frequency ranges using a signal received from the transmitter, and a receiver of information about the quality of the channels for transmission on the feedback channel inf rmatsii channel quality measured for each of the frame cells to the transmitter. 27. The data receiving apparatus according to claim 26, wherein the cell frames are divided into cell frames for transmitting packet data for transmitting packet data and cell frames for transmitting control data for transmitting control data, and channel quality information is transmitted via the feedback channel through cell transmission frames management data. 28. The data receiving apparatus according to claim 27, wherein at least one of the frame cells is designated as a control data transmission frame cell. 29. The data receiving apparatus according to claim 26, wherein the sub-frequency from the sub-frequency ranges constituting each of the time-frequency cells is hopped in accordance with a predetermined frequency hopping pattern. 30. The data receiving apparatus according to claim 26, wherein each of the time-frequency cells is expanded using a predetermined code for allocating a frequency band to individual channels.